CN116378109A - Anti-scouring structure of floating crane integrated pile foundation, manufacturing and construction method - Google Patents

Abstract

The invention discloses a floating crane integrated pile foundation scour prevention structure in the technical field of ocean engineering, and a manufacturing and construction method thereof, comprising a rubber liner; the concrete shell is wrapped on the outer side of the rubber liner and fixedly connected with the rubber liner; the steel reinforcement framework is pre-buried in the concrete shell, and the longitudinal ends and the transverse ends of the steel reinforcement framework axially penetrate through the concrete shell and are respectively and correspondingly pre-provided with a horizontal hook and a vertical hook; the hanging ring is arranged at the top of the concrete shell and is in prefabricated connection with the steel reinforcement framework; the exhaust hole is arranged at the top of the concrete shell and is communicated with the inner cavity of the rubber liner; the water inlet is arranged at the bottom of the concrete shell and is communicated with the inner cavity of the rubber liner. The scour prevention structure can be transported to the pile foundation position by adopting a floating and lifting combined mode, and is filled into a cavity to sink to the seabed surface after accurate positioning, so that the requirements of a construction ship machine can be effectively reduced, the water construction procedures are reduced, and the construction cost is reduced.

Description

Anti-scouring structure of floating crane integrated pile foundation, manufacturing and construction method

Technical Field

The invention relates to the technical field of ocean engineering, in particular to a pile foundation scour prevention structure.

Background

The harbor engineering construction generally adopts pile foundations to transmit upper load to soil layers with good bearing performance deeper in the ground so as to meet the requirements of bearing capacity and settlement. Pile foundations are subjected to the action of waves and tide for a long time in a complex water area environment, soil bodies around the pile foundations are continuously eroded and scour, and particularly in strong current areas such as river ports or tidal channels, the scour phenomenon is very remarkable, and the safety of harbor engineering is seriously influenced.

The existing common pile foundation anti-scouring mode mainly comprises anti-scouring schemes such as a stone throwing scheme, a sand quilt scheme, solidified soil and a soft mattress, wherein the stone throwing scheme has the advantage of simple construction, but a sinking path during stone throwing cannot be controlled, a foundation is easy to strike and an anti-corrosion coating is easy to damage, and the service life of a pile foundation is influenced; in the sand quilt scheme, geotextiles for manufacturing sand bags are easy to age and cause the damage of the sand quilt, so that the sand is lost, and a pile foundation cannot be effectively protected; the solidified soil scour prevention scheme has a better theoretical effect on the local scour of a silted area, but has poorer protection effect on the whole scour seabed because of no effect on the edge scour; the soft mattress has better theoretical effect, but is difficult to construct and is rarely used in practice.

Therefore, how to solve the problem that the existing anti-scouring structure cannot achieve the anti-scouring effect, the construction convenience and the economy is a technical problem to be solved by the technicians in the field.

Disclosure of Invention

Therefore, the invention aims to provide an anti-scouring structure of a floating crane integrated pile foundation, which solves the technical problem that the existing anti-scouring structure cannot achieve the anti-scouring effect, construction convenience and economy.

The technical scheme adopted by the invention is as follows: an anti-scour structure of a floating crane integrated pile foundation, the anti-scour structure comprises a plurality of cavity structures connected by hooks, and the cavity structures comprise:

a rubber liner;

the concrete shell is wrapped on the outer side of the rubber liner and fixedly connected with the rubber liner;

the steel reinforcement framework is pre-buried in the concrete shell and comprises transverse steel bars, longitudinal steel bars and vertical steel bars, the transverse two ends of the transverse steel bars penetrate through the concrete shell along the transverse direction, one end of each transverse steel bar is prefabricated with a horizontal hook, and the other end of each transverse steel bar is prefabricated with a vertical hook; the two longitudinal ends of the longitudinal steel bar penetrate through the concrete shell along the longitudinal direction, a horizontal hook is prefabricated at one end of the longitudinal steel bar, and a vertical hook is prefabricated at the other end of the longitudinal steel bar; the top ends of the vertical steel bars penetrate through the concrete shell along the vertical direction;

the lifting ring is arranged at the top of the concrete shell and is in prefabricated connection with the reinforcement cage;

the exhaust hole is arranged at the top of the concrete shell and is communicated with the inner cavity of the rubber liner;

the water inlet is arranged at the bottom of the concrete shell and is communicated with the inner cavity of the rubber liner;

the horizontal hooks and the vertical hooks are equal in size and vertical in direction.

Preferably, the top end of the vertical steel bar is prefabricated with a hanging ring.

Preferably, the outer surface of the rubber inner container is provided with a concave-convex part which can improve the connection strength of the rubber inner container and the concrete shell.

Preferably, geotextile and bionic grass are pre-buried at the bottom of the concrete shell.

Preferably, a plurality of the cavity structures are linearly distributed along the longitudinal direction and the transverse direction, and two adjacent cavity structures are connected through a horizontal hook and a vertical hook in a lap joint mode.

Preferably, the horizontal hooks and the vertical hooks of two adjacent cavity structures are in single-layer lap joint or double-layer lap joint; and a rubber protection pad is arranged between the cavity structure and the pile foundation.

The second object of the present invention is to provide a method for manufacturing an anti-scour structure of a floating crane integrated pile foundation, which comprises the following steps:

s10: building a binding reinforcement cage in the mold;

s20: placing the rubber inner container in the inner cavity of the steel reinforcement framework and sealing by inflation;

s30: pouring concrete to fill the gap between the rubber liner and the mold;

s40: the concrete shell is fixedly formed on the outer side of the rubber liner through curing, and an exhaust hole and a water inlet hole which are communicated with the inner cavity of the rubber liner are formed on the concrete shell;

s50: the sealing plug in the exhaust hole is pulled out to deflate the rubber liner, and the concrete shell is fixedly connected with the rubber liner.

The third object of the invention is to provide a construction method of an anti-scouring structure of a floating crane integrated pile foundation, which comprises the following steps:

s100: hooking and connecting the plurality of cavity structures into an anti-scouring structure with a required shape;

s200: and transporting the scour prevention structure to a preset sea area and sinking to the seabed surface at one side of the pile foundation.

Preferably, the step S200 includes: firstly, the anti-scouring structure is suspended in water, the anti-scouring structure is hauled to a sinking position in a floating mode, and then the rope is pulled to pull out the plugging plug in the water inlet hole, so that the anti-scouring structure is integrally sunk.

Preferably, the step S200 includes: firstly, the anti-scouring structure is hung on a transport ship, the anti-scouring structure is transported to a sinking station in a shipping mode, then the plugging plug in the water inlet hole is pulled out, and the anti-scouring structure is hung in water and is sunk through a hanging frame on the transport ship.

The invention has the beneficial effects that:

1. the invention forms the cavity in the cavity body structure through the rubber liner, thereby not only reducing the weight of the anti-scouring structure and the use amount of concrete, but also reducing the manufacturing cost, realizing the floating and sinking of the anti-scouring structure through the exhaust and water inlet of the rubber liner, and reducing the requirements of the ship transporting machine.

2. The anti-scour structure is formed by overlapping and connecting the plurality of cavity structures through the horizontal hooks and the vertical hooks of the steel reinforcement framework, and the plurality of cavity structures can be overlapped and assembled into the anti-scour structure with any shape due to better overlapping and connecting flexibility, can be better adapted to submarine topography, and can also overlap double layers or single layers according to site conditions. Meanwhile, the cavity structures are all prefabricated modules, the overall combination is good, various shapes can be formed for scouring of the seabed surface, and the cavity structures with any shapes can be designed into anti-scouring structures, such as circles, squares, rectangles and the like, only by splicing and combining a certain number of cavity structures, so that various field requirements are met. Besides, the method can be used for filling some punching pits, the area of the punching pits is determined according to field measurement, and the shape of the punching pits is quickly assembled on site to sink in place.

3. The reinforcement cage and the cavity structure can be prefabricated rapidly, if the design discovers that the site situation is different from the original design situation, the reinforcement cage and the cavity structure can be assembled and supplemented rapidly, and the reinforcement cage and the cavity structure can be assembled and connected rapidly on land and on a ship, so that the practicability of the anti-scouring structure is improved.

4. The steel reinforcement framework is positioned on the outer side of the rubber inner container, the steel reinforcement framework can limit the volume and the position of the rubber inner container when the cavity structure is manufactured, the thickness of the cast concrete shell and the size of the cavity can be controlled by matching with the forming die, the buoyancy of the cavity structure can be quantitatively controlled, the large-scale and batch manufacturing is convenient, the construction cost of the anti-scouring structure is further reduced, and the anti-scouring structure has better economy. Meanwhile, the concrete shell is tightly wrapped on the outer side of the waterproof rubber liner, so that a cavity can be formed in the concrete shell, floating of a cavity structure is realized, seawater can be prevented from penetrating into the inner cavity through the concrete shell during floating, and floating safety of an anti-scouring structure is ensured; in addition, the rubber liner is low in purchase price, so that the manufacturing cost of the anti-scour structure is reduced to the greatest extent on the premise of meeting the floating requirement of the anti-scour structure, and the economical efficiency of the anti-scour structure is improved.

5. The steel bar framework has the following five functions: the steel reinforcement framework can flexibly connect two adjacent cavity structures (hook connection), so that the adaptability of the assembled integral scour prevention structure to submarine topography is improved; the second is: the reinforced concrete framework and the concrete shell are mutually matched to form a reinforced concrete structure, so that the reinforced concrete structure is simple in structure and convenient to manufacture, and the structural strength of the cavity structure can be improved; the third is: the reinforcement cage can replace a concrete shell to transmit force, has good connection integrity and simple and clear stress, ensures the integral stability of the structure and can be fully suitable for the construction modes such as hoisting, floating transportation, paving and the like which are common at sea; the fourth is: the steel reinforcement framework can limit the volume and the position of the rubber liner, the thickness of the concrete shell and the size of the cavity can be accurately controlled according to actual demand calculation results, so that the structure is convenient to float, and the formed cavity also reduces the use of concrete materials; fifth is: the prefabricated lifting hook of the steel reinforcement framework serves as a main stress point for lifting while serving as a vertical framework, so that lifting and construction of the anti-scouring structure are facilitated.

Drawings

FIG. 1 is a schematic view of a cavity structure of the present invention;

FIG. 2 is a diagram of the positional relationship between a rubber bladder and a reinforced cage;

FIG. 3 is a front view of FIG. 2;

FIG. 4 is a top view of FIG. 2;

fig. 5 is a perspective view of a reinforcement cage;

FIG. 6 is a perspective view of an integrated pile foundation scour protection of the floating crane;

FIG. 7 is a front view of an integrated pile foundation scour protection of the floating crane;

FIG. 8 is a schematic illustration of the connection of a horizontal hook and a vertical hook;

FIG. 9 is one of reference diagrams of the use state of the floating crane integrated pile foundation scour prevention structure;

FIG. 10 is a second reference view of the use status of the floating crane integrated pile foundation anti-scour structure;

FIG. 11 is a third view of the use status of the floating crane integrated pile foundation anti-scour structure;

FIG. 12 is a view showing a reference view of a use state of the floating crane integrated pile foundation anti-scour structure;

the reference numerals in the drawings illustrate:

10. a cavity structure;

20. pile foundation;

30. a rubber pad;

100. a rubber liner;

200. a concrete shell;

300. a reinforcement cage;

310. transverse steel bars; 320. longitudinal steel bars; 330. vertical steel bars; 340. a horizontal hook; 350. a vertical hook;

400. a hanging ring;

500. an exhaust hole;

600. and a water inlet hole.

Detailed Description

The following describes the embodiments of the present invention in further detail with reference to the accompanying drawings. These embodiments are merely illustrative of the present invention and are not intended to be limiting.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, in the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more.

1-12, an anti-scour structure of a floating crane integrated pile foundation is used for anti-scour protection of a pile foundation of offshore wind power; the anti-scouring structure is formed by overlapping a plurality of cavity structures 10; the cavity structure 10 includes:

a rubber bladder 100.

And the concrete shell 200 is wrapped outside the rubber liner 100, and the concrete shell 200 is fixedly connected with the rubber liner 100.

The reinforcement cage 300, the reinforcement cage 300 is pre-buried in the concrete housing 200, and the reinforcement cage 300 includes transverse reinforcement 310, longitudinal reinforcement 320 and vertical reinforcement 330; wherein, the transverse steel bar 310 is pre-embedded in the concrete casing 200 along the transverse direction, one end of the transverse steel bar 310 extends through the concrete casing 200 along the transverse direction and is integrally formed and prefabricated with a horizontal hook 340, and the other end of the transverse steel bar 310 extends through the concrete casing 200 along the transverse direction and is integrally formed and prefabricated with a vertical hook 350; the longitudinal steel bars 320 are pre-embedded in the concrete casing 200 along the longitudinal direction, one end of each longitudinal steel bar 320 longitudinally extends through the concrete casing 200 and is integrally formed and prefabricated with a horizontal hook 340, and the other end of each longitudinal steel bar 320 longitudinally extends through the concrete casing 200 and is integrally formed and prefabricated with a vertical hook 350; wherein the horizontal hooks 340 and the vertical hooks 350 are equal in size and perpendicular in direction, i.e., the vertical hooks 350 face upward or downward, and the horizontal hooks 340 face forward or backward.

The hanging ring 400 is arranged at the top of the concrete shell 200, and the hanging ring 400 is prefabricated and formed at the top end of the reinforcement cage 300.

The air vent 500 is provided at the top of the concrete casing 200, and the air vent 500 communicates with the inner cavity of the rubber bladder 100.

The water inlet hole 600 is provided at the bottom of the concrete casing 200, and the water inlet hole 600 is communicated with the inner cavity of the rubber liner 100.

The hollow structure is adopted, the steel reinforcement framework 300 is arranged on the periphery of the rubber liner 100, the concrete shell 200 is cast and molded on the periphery of the rubber liner 100, and the structural strength of the hollow cavity structure 10 can be improved through the mutual matching of the steel reinforcement framework 300 and the concrete shell 200; the cavity is formed in the cavity body structure 10 through the rubber liner 100, so that the weight of the anti-scouring structure can be reduced, the use amount of concrete is reduced, the manufacturing cost is reduced, the floating and sinking of the cavity body structure 10 can be realized through the exhaust and water inlet of the rubber liner 100, and the requirements of a hauling ship machine are reduced; by prefabricating the horizontal hooks 340 and the vertical hooks 350 at the two transverse and longitudinal ends of the reinforcement cage 300, the two adjacent cavity structures 10 are conveniently connected in a lap joint manner, so that the construction of the anti-scouring structure is facilitated, and the standardized and large-scale production of the anti-scouring structure can be realized; the impact force of water flow, which is applied to the concrete casing 200, is transmitted through the transverse steel bars 310 or the longitudinal steel bars 320, so that the influence of the impact force of water flow on the concrete casing 200 can be reduced, and the stability of the anti-scouring structure is improved; meanwhile, the hanging ring 400 is prefabricated at the top of the reinforcement cage 300, so that the cavity structure 10 can be lifted conveniently, and the manufacturing cost of the hanging frame is saved.

In a specific embodiment, as shown in fig. 2, 3, 4 and 5, the vertical steel bars 330 are pre-embedded in the concrete casing 200 along the vertical direction, and the top ends of the vertical steel bars 330 vertically extend through the concrete casing 200 and are integrally molded with the hanging rings 400.

Preferably, as shown in fig. 5, the reinforcement cage 300 is a rectangular frame, and is formed by binding and fixing four transverse reinforcement bars 310, four longitudinal reinforcement bars 320 and four vertical reinforcement bars 330, and the top end of each vertical reinforcement bar 330 is integrally molded and prefabricated with a hanging ring 400; the part of the reinforcement cage 300 exposed out of the concrete casing 200 is provided with an anti-corrosion coating, and the hanging ring 400 is also provided with an anti-corrosion coating.

As shown in fig. 5, the horizontal hooks 340 in this embodiment are horizontally disposed as a whole, that is, the axis of the hook is perpendicular to the horizontal plane, and all the horizontal hooks 340 are directed to one side and are provided with an anti-corrosion coating; the vertical hooks 350 are vertically arranged as a whole, that is, the axes of the hooks are parallel to the horizontal plane, and all the vertical hooks 350 face to one side and are provided with an anti-corrosion coating. Meanwhile, the lateral direction in this application refers to the double-arrow direction in fig. 5, the longitudinal direction refers to the solid line single-arrow direction in fig. 5, and the vertical direction refers to the broken line single-arrow direction in fig. 5.

In one embodiment, the outer surface of the rubber liner 100 is provided with a concave-convex portion (not shown) capable of increasing the connection strength between the rubber liner 100 and the concrete casing 200; that is, after concrete is poured on the outer side of the inflated rubber bladder 100, the cured concrete casing 200 can be fixedly connected with the rubber bladder 100, and after the rubber bladder 100 is deflated, the concrete casing 200 is still fixedly connected with the rubber bladder 100.

Specifically, the concave-convex portion may be a pattern or a concave-convex shape.

In one embodiment, geotextile and bionic grass are pre-buried at the bottom of the concrete casing 200, that is, geotextile and bionic grass are laid under the reinforcement cage 300 before concrete is poured. Thus, sediment around the pile foundation 20 can be prevented from being hollowed out by utilizing the reverse filtering function of geotextile and the turbulence function of bionic grass.

In one embodiment, as shown in fig. 6, 7 and 8, the anti-scour structure is formed by a plurality of cavity structures 10 which are linearly distributed in the transverse and/or longitudinal directions and overlap-connected, and can be enclosed at least on one side of the pile foundation 20.

Preferably, for foundations requiring higher field adaptability, such as uneven foundation surfaces, horizontal hooks 340 and vertical hooks 350 on the upper layers of two adjacent cavity structures 10 which are transversely distributed and/or longitudinally distributed form single-layer lap joint; for large water areas with large wind waves on site, the horizontal hooks 340 and the vertical hooks 350 of the upper layer and the lower layer of the adjacent two cavity structures 10 which are longitudinally distributed and/or transversely distributed form double-layer lap joint.

More preferably, a rubber grommet 30 is provided between the cavity structure 10 and the pile foundation 20 for reducing the impact of the scour protection on the pile foundation 20.

In an embodiment, as shown in fig. 1, 2 and 5, a method for manufacturing an anti-scouring structure of a floating crane integrated pile foundation includes the following steps:

s10: the binding reinforcement cage 300 is erected in the mold, and the horizontal and longitudinal ends of the reinforcement cage 300 are respectively and correspondingly provided with a horizontal hook 340 and a vertical hook 350.

The method comprises the following steps: binding and fixing four transverse steel bars 310, four longitudinal steel bars 320 and four vertical steel bars 330 into a rectangular steel bar framework 300 in a mould; wherein, one end of the transverse steel bar 310 and one end of the longitudinal steel bar 320 are integrally molded and prefabricated with a horizontal hook 340, and the other end of the transverse steel bar 310 and the other end of the longitudinal steel bar 320 are integrally molded and prefabricated with a vertical hook 350; the hanging ring 400 is integrally formed and prefabricated at the top end of the vertical steel bar 330.

In other embodiments, the cage 300 may have other shapes, such as oval.

S20: the rubber bladder 100 is placed in the inner cavity of the reinforcement cage 300 and is sealed by inflation.

The method comprises the following steps: the rubber inner container 100 is placed in the inner cavity of the reinforcement cage 300, the top of the rubber inner container 100 is communicated with the exhaust pipe, the bottom of the rubber inner container 100 is communicated with the water inlet pipe, the rubber inner container 100 is inflated through the exhaust pipe at the top (the water inlet pipe is sealed through the plugging plug), then the exhaust pipe at the top of the rubber inner container 100 is plugged by the plugging plug, and the reinforcement cage 300 has a limiting effect on the volume of the rubber inner container 100.

S30: the cast concrete fills the gap between the rubber bladder 100 and the mold.

The method comprises the following steps: concrete is poured into the mold until the concrete fills the gap between the rubber bladder 100 and the mold, that is, the concrete is wrapped outside the entire reinforcement cage 300, and the exhaust pipe and the water inlet pipe on the rubber bladder 100 are exposed to the concrete.

S40: the concrete casing 200 is fixedly formed at the outer side of the rubber liner 100 through curing, and the exhaust hole 500 and the water inlet hole 600 communicated with the inner cavity of the rubber liner 100 are formed on the concrete casing 200.

S50: the sealing plug in the exhaust hole is pulled out to deflate the rubber liner 100, and the concrete shell 200 is still fixedly connected with the rubber liner 100.

The method comprises the following steps: after the concrete curing is finished, after the concrete is solidified into the concrete shell 200 and is fixedly connected with the rubber liner 100, the sealing plug in the exhaust pipe is pulled out, and the deflated rubber liner 100 is still fixedly connected with the concrete shell 200.

As shown in fig. 9, 10, 11 and 12, an embodiment of a construction method of an anti-scour structure of a floating-crane integrated pile foundation, the method comprises the following steps:

s100: the plurality of cavity structures 10 are snap-connected in the longitudinal and/or transverse direction into a scour protection of a desired shape.

The method comprises the following steps: the plurality of cavity structures 10 are linearly distributed in the longitudinal direction and/or the transverse direction and the horizontal hooks 340 and the vertical hooks 350 of the adjacent two cavity structures 10 are lap-jointed, thereby forming an anti-scour structure capable of being matched with the pile foundation 20.

S200: the scour protection is transported to a predetermined sea area and lowered onto the seabed on the side of the pile foundation 20.

In one embodiment is: firstly, the assembled anti-scouring structure is lifted to the sea surface through the lifting ring 400, and a rope for sealing and blocking in the water inlet hole 600 is tied on a winch for hauling the ship; and then the anti-scouring structure is hauled to the designated pile foundation 20 by adopting a floating mode, and a winch is started after accurate positioning to pull off the plugging plugs in all the water inlets 600, so that the inner cavity of the rubber liner 100 is filled with water, and the anti-scouring structure is wholly sunk to the seabed surface.

In another embodiment is: the assembled anti-scouring structure is lifted to a transport ship through the lifting rings 400, transported to the position of the appointed pile foundation 20 through the transport ship, then the anti-blocking in all the water inlets 600 are pulled down after accurate positioning, and the anti-scouring structure is lifted to sea water through the lifting frame on the transport ship, so that the inner cavity of the rubber liner 100 is filled with water, and the anti-scouring structure is wholly sunk to the sea bed surface.

Compared with the prior art, the application has at least the following beneficial technical effects:

1. the scour prevention structure in this application comprises rubber inner bag, reinforcement cage and concrete shell, can realize standardized and normalized production.

2. The scour prevention structure in the application can adopt different transportation forms according to the construction environment conditions; when floating hauling is adopted, the requirements of a ship construction machine can be effectively reduced, the water construction procedures are reduced, and the construction cost is saved; after floating hauling to appointed position, the scour prevention structure can sink to the seabed surface through filling water, compares with sand quilt and soft row scour prevention scheme, can save the cost of manufacture of lifting frame. When the traditional shipping mode is adopted, compared with the entity anti-scouring structure, the internal hollow anti-scouring structure has small weight, and the requirements of a hauling ship machine can be reduced.

3. The anti-scouring structure can be flexibly connected according to field conditions; for the foundation with higher field adaptability requirement, the adjacent cavity structures are only hooked to connect the upper row of two longitudinal steel bars or transverse steel bars, so that the anti-scouring structure locally has a certain rotational deformation capacity, and is better adapted to the topography; for a large water area with wind waves on site, two adjacent cavity structures can be hooked to connect an upper row of four transverse steel bars or a lower row of four longitudinal steel bars, so that the overall stability of the anti-scouring structure is ensured.

4. The cavity structure can be hooked and assembled into an anti-scouring structure with any shape, and the application range of ocean currents and geological environments is wide.

5. The rubber in this application waterproof nature is good, and low price adopts the mode that rubber inner bag and concrete shell combined to form scour protection structure, and waterproof performance requirement to surface concrete is lower, is favorable to saving the cost.

6. The steel reinforcement framework in the application not only can limit the volume of the rubber liner, but also has the functions of connection and hanging points, and is beneficial to saving the manufacturing cost, transportation and installation cost.

7. The top of scour protection structure is provided with four hoisting points, and arbitrary hoisting points can be selected for hoisting according to construction design requirements during hoisting.

8. The geotechnical cloth and the bionic grass are embedded in the bottom of the concrete shell, so that the concrete shell is convenient to manufacture and construct, and the scour prevention effect can be further guaranteed.

9. The shape of the bottom of the concrete shell in the application can be adjusted according to actual site conditions, the applicability of the seabed is increased, and the anti-scouring effect is ensured.

The foregoing is merely a preferred embodiment of the present invention, and it should be noted that modifications and substitutions can be made by those skilled in the art without departing from the technical principles of the present invention, and these modifications and substitutions should also be considered as being within the scope of the present invention.

Claims (8)

1. The utility model provides a floating crane integral type stake basis scour protection structure, its characterized in that, scour protection constructs including a plurality of hook-and-loop connected cavity body structure (10), cavity body structure (10) include:

a rubber liner (100);

the concrete shell (200) is wrapped on the outer side of the rubber liner (100) and fixedly connected with the rubber liner (100);

the steel reinforcement framework (300), steel reinforcement framework (300) are pre-buried in concrete shell (200), and steel reinforcement framework (300) include horizontal reinforcing bar (310), vertical reinforcing bar (320) and vertical reinforcing bar (330), horizontal both ends of horizontal reinforcing bar (310) run through concrete shell (200) along the transverse direction, just horizontal hook (340) have been prefabricated to one end of horizontal reinforcing bar (310), and vertical hook (350) have been prefabricated to the other end; the two longitudinal ends of the longitudinal steel bars (320) penetrate through the concrete shell (200) along the longitudinal direction, one end of the longitudinal steel bars (320) is prefabricated with a horizontal hook (340), and the other end is prefabricated with a vertical hook (350); the top ends of the vertical steel bars (330) penetrate through the concrete shell (200) along the vertical direction;

the lifting ring (400) is arranged at the top of the concrete shell (200) and is in prefabricated connection with the reinforcement cage (300);

the exhaust hole (500) is formed in the top of the concrete shell (200) and is communicated with the inner cavity of the rubber liner (100);

the water inlet hole (600) is formed in the bottom of the concrete shell (200) and is communicated with the inner cavity of the rubber liner (100);

the horizontal hooks (340) and the vertical hooks (350) are equal in size and perpendicular in direction.

2. The scour prevention structure of a floating crane integrated pile foundation according to claim 1, characterized in that the outer surface of the rubber liner (100) is provided with a concave-convex part capable of improving the connection strength of the rubber liner (100) and the concrete shell (200); geotechnical cloth and bionic grass are pre-buried at the bottom of the concrete shell (200).

3. The floating crane integrated pile foundation scour prevention structure according to claim 1, wherein a plurality of the cavity structures (10) are linearly distributed in the longitudinal direction and the transverse direction, and two adjacent cavity structures (10) are in lap joint connection through a horizontal hook (340) and a vertical hook (350).

4. The integrated pile foundation scour protection of claim 1, wherein the horizontal hooks (340) and vertical hooks (350) of two adjacent cavity structures (10) overlap in a single layer or in a double layer; a rubber protection pad (30) is arranged between the cavity structure (10) and the pile foundation (20).

5. A method for manufacturing the floating crane integrated pile foundation scour prevention structure according to any one of claims 1 to 4, characterized by comprising the steps of:

s10: building a binding reinforcement cage (300) in the die;

the steel reinforcement framework (300) comprises a transverse steel bar (310), a longitudinal steel bar (320) and a vertical steel bar (330) which are fixedly connected in a binding way, wherein a horizontal hook (340) and a vertical hook (350) are respectively and correspondingly prefabricated at the transverse two ends of the transverse steel bar (310), a horizontal hook (340) and a vertical hook (350) are respectively and correspondingly prefabricated at the longitudinal two ends of the longitudinal steel bar (320), and the horizontal hook (340) and the vertical hook (350) are equal in size and vertical in direction; a hanging ring (400) is prefabricated at the top end of the vertical hook (350);

s20: placing the rubber inner container (100) in an inner cavity of the steel reinforcement framework (300) and sealing the inner cavity by inflation;

s30: filling the gap between the rubber liner (100) and the mold with concrete;

s40: the concrete shell (200) is fixedly formed outside the rubber liner (100) through curing, and an exhaust hole (500) and a water inlet hole (600) which are communicated with the inner cavity of the rubber liner (100) are formed on the concrete shell (200);

s50: the sealing plug in the exhaust hole (500) is pulled out to deflate the rubber liner (100), and the concrete shell (200) is fixedly connected with the rubber liner (100).

6. A construction method of an anti-scour structure of a floating crane integrated pile foundation, which is used for the construction of the anti-scour structure of the floating crane integrated pile foundation according to any one of claims 1 to 4, characterized by comprising the following steps:

s100: hooking and connecting a plurality of cavity structures (10) into an anti-scouring structure with a required shape;

s200: the scour protection is transported to a predetermined sea area and lowered onto the seabed surface at one side of the pile foundation (20).

7. The method for constructing the scour prevention structure of the integrated pile foundation of the floating crane according to claim 6, wherein the step S200 comprises: the anti-scouring structure is firstly suspended into water, is hauled to a sinking position in a floating mode, and then the blocking plug in the water inlet hole (600) is pulled out by pulling the rope, so that the anti-scouring structure is wholly sunk.

8. The method for constructing the scour prevention structure of the integrated pile foundation of the floating crane according to claim 6, wherein the step S200 comprises: firstly, the anti-scouring structure is lifted to a transport ship, the anti-scouring structure is transported to a sinking station in a shipping mode, then the plugging plug in the water inlet hole (600) is pulled out, and the anti-scouring structure is lifted into water and is sunk through a hanger on the transport ship.

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